H04L1/00—Arrangements for detecting or preventing errors in the information received

H04L2001/0092—Error control systems characterised by the topology of the transmission link

Description

1305469 发明, INSTRUCTION DESCRIPTION: TECHNICAL FIELD OF THE INVENTION The present invention relates to wireless (broadcast) communication, and more particularly to improvements in providing a High Speed Upload Packet Access (HSUPA) scheme. [Prior Art]

An Unviersal Mobile Telecommunications System (UMTS) is a third-generation mobile communication system derived from the European Global Communications System (GS '), which aims to be based on a GSM core network and W-CDMA (Wideband Code multiplex access) Wireless connectivity technology provides an improved mobile communication service. Figure 1 illustrates an exemplary basic structure of a UMTS network (100). The U Μ TS is roughly divided into a terminal 100 (e.g., mobile station, user equipment, etc.), a UMTS Terrestrial Radio Access Network (UTRAN) 120, and a core network ( CN) 1 30. The UTRAN 120 is comprised of one or more communication network subsystems (Radio Network Sub-systems, RNS: 121, 122). Each RNS consists of a Broadcast Network Controller (RNC: 1 23, 1 24) and one or more base stations (such as Node B: 1 2 5, 1 2 6) managed by the RNC. . One or more cells (c e 11 ) are present at each node B. The RN C (1 2 3, 1 2 4 ) handles the allocation and management of broadcast resources and serves as an access point for the core network 130. The Node B (1 2 5, 1 2 6 ) thus acts as an access point for the UTRAN 120 to the terminal 100. Furthermore, the 1305469 RNC (1 23, 1 24) allocates and manages broadcast resources as an access point to the core network 130. There is an interface between the various network fabric elements to allow for the exchange of data for communication with each other. Figure 2 illustrates a broadcast interface protocol (structure) between the terminal 1 and the utraN 12A in accordance with a 3GPP VoIP technology. Here, the broadcast access interface has a horizontal layer comprising a physical layer, a data link layer and a network layer and has a user plane for transmitting data information and for transmitting control signals. A vertical plane of a control surface. The user plane is an area to which a user's communication information (such as voice data, IP (Internet Protocol) packets, etc.) is transmitted. The control plane is an area where transmission control information (such as the interface of the network, maintenance and management of the call, etc.) is visited. Furthermore, as shown in FIG. 2, the protocol layer can be divided into three lower layers of an Open System Interconnection (〇Sl) scheme well known in the wireless (mobile) communication system technology. A first layer (L1), a second layer (L2), and a third layer (L3). The first layer (L1) is a physical layer (PHY) that provides information transfer services to higher layers by using various broadcast transmission technologies. The first layer is connected to a MAC layer located therethrough through a transmission channel through which the media access control (MAC) layer and the physical layer communicate with each other. Furthermore, between the different physical layers (i.e., between the transmission side and the individual physical layers on the receiving side), the data is transmitted through a physical channel. The Media Access Control (MAC) layer processes the mapping between the logical channel and the pass 1305469 channel and provides one of the M A C parameters to reallocate services for allocation and reallocation of broadcast (wireless) resources. The MAC layer of the first layer (L2) is connected to a higher layer called a Radio Link Control (RLC) layer through a logical channel and provides various logical channels depending on the type of information to be transmitted. In other words, the mac layer serves a higher layer (the RLC layer) through a logical channel.

The second layer (L2) of the RLC layer can support reliable data transmission' and can perform a segmentation and concatenation function on multiple RLC Service Data Units (RLC SDUs) transmitted from a higher layer. . A packet data convergence protocol (PDCP) layer is located at a higher level of the RLC layer, which allows the data to be efficiently transmitted through a broadcast interface and through a network protocol with a relatively small amount of bandwidth. The radio resource control (RRC) layer located at the lowest part of the third layer (L3) is defined only in the control plane, which controls the transmission channel and the physical channel with respect to the configuration, the reconfiguration, and The release of the radio bearer (RBS). The broadcast carrier service refers to a service in which the second layer (L2) provides a data transfer between the terminal (UE) 100 and the UTRAN 1 20 to ensure a predetermined quality of service of the UE and the UTRAN. In general, the broadcast carrier (RB) establishment refers to adjusting the protocol layer required to provide a specific service and the channel characteristics of the channel, and setting the substantial parameters individually and the operation method of 7 Ϊ 305469. In the RBs, the specific RB used between the UE and the utrAN for exchanging RRC messages or NAS messages is referred to as a SRb (Signaling Radio Bearer). When a srb is built

When standing between a specific UE and the UTRAN, an rrc connection exists between the UE and the UTRAN. A UE having an rrc connection is referred to as being in RRC connected mode and a UE having no rrc connection is said to be in an idle mode. When a UE is in an rrc connected mode, the RNC determines the cell in which the UE is located (and the rNc determines the location of the UE in the cell unit) and manages the UE. The MAC layer of the second layer provides a service to a higher layer of a Broadcast Link Control (RLC) layer through a logical channel. The MAC layer is subdivided into several types of sublayers, such as a MAC-d sublayer and a MAC-e sublayer, depending on the type of transport channel being managed. A related art structure of a dedicated chaneel (DCH) and an enhanced dedicated channel (E-DCH) is illustrated in FIG. As shown in the figure, the DCH 14 and the E-DCH 16 are dedicated transmission channels used by a mobile terminal. In particular, the E-DCH 16 is used to transmit data to the UTRAN 6 at a high speed relative to the DCH 14. In order to transmit data at a high speed, various techniques such as a HARQ (Hybrid HARQ), an AMC (Adaptive Modulation and Coding, Adaptive Modulation and Coding), a Node B control schedule, and the like can be used for the E-DCH. For E-DCH 166, the Node B 1 2 transmits the connection control information to a mobile terminal 2 to control the E-D C Η transmission of the mobile terminal 2. The

S 1305469 The lower link control information may include the HARQ response information (ACK/NACK), the channel quality information (CQI) of the AMC, the E-DCH transmission rate information, the E_D (: H transmission start time, and the transmission). Period information and a transmission block size information of the Node B control schedule, and the like.

At the same time, the terminal 2 transmits the upload control information to the node b 12. The upload control information may include E-DCH transmission rate request information 'UE buffer status information and UE B power status information of the Node B control schedule. The E-D C Η 16 upload control information and the lower link control information are transmitted through a physical control channel such as an E-DPCCH (Enhanced Dedicated Physical Data Channel). For the E-DCH 16, a MAC-d flow 18 is defined between the MAC-d sublayer 24 and the MAC-e sublayer 26. In this case, a dedicated logical channel is mapped to a MAC-d flow 'the MAC-d flow is mapped to the transmission channel E - DC Η 1 6 ' and the E-DC Η 16 is mapped to a physical channel E-DPDCH (Enhanced Dedicated Entity Data Channel) 20. Furthermore, the dedicated logical channel can be directly mapped to the DCH 14 - which is also a - pass-through channel, and the DCH 14 is mapped to the DPDCH (Dedicated

Physical Data Channel, 22 ° As shown in Figure 3, the MAC-d sublayer 24 manages the DCH 14 - a dedicated transmission channel for a particular terminal. The MAC-e sub-layer 26 is used to transmit a transmission channel for high-speed uploading of data. A MAC-d sublayer on a transmission side is from a higher layer, that is, the RLC layer 1305469

A MAC-d PDU (Protocpl Data Unit) is established at a received MAC-d SDU (Service Data Unit). In addition, a MAC-d sublayer on a receiving side replies to the MAC-d SDU from a MAC-d PDU received from a lower layer and transmits it to a higher layer. The MAC-d sublayer may transmit the MAC-d PDU to the MAC-e sublayer through a MAC-d process, or transmit the MAC-d PDU to a physical layer through the DCH. The MAC-d sublayer on the receiving side then replies to the MAC-d SDU by using a MAC-d header included in the MAC-d PDU and then transmits the MAC-d SDU to the higher layer. The MAC-e sublayer of the transmitting side establishes a MAC-e PDU by the MAC-d PDU established by the MAC-e SDU and received from the MAC-d sublayer. Alternatively, the MAC-e sublayer of the receiving side replies to the MAC-e SDU by the MAC-e PDU received from the physical layer and transmits it to a higher layer. In this case, the MAC-e sublayer transmits the MAC-e PDU to the physical layer through the E-DCH. The MAC-e sublayer of the receiving side then replies to the MAC-e SDU with a MAC-e header included in the MAC-e PDU and then transmits it to the higher layer. A contract model of a related art E - D C 说明 is illustrated in FIG. As shown in the figure, the MAC-e sublayer supporting the E-DHC is located at a lower position of the UTRAN 26 and the MAC-d sublayer of the terminal (UE) 28. The MAC-e sublayer 30 of the UTRAN 26 is located in Node B. The MAC-e sublayer is present in each terminal 28. In contrast, the MAC-d sublayer 34 of the UTRAN 26 is located in an SRNC for managing a corresponding terminal 28. Each terminal 28 includes a MAC-d sublayer 36. 10

1305469 The Qos for a process in which a UE is mapped onto the Ε-DCH is maintained by the Serving Node B and the UE. In addition to these mechanisms, the MAC-d Process/Logical Channel (F F S ) guaranteed bit rate service is also supported through non-scheduled transmission. A process for using non-scheduled transmission is defined by the SRNC and provided in the UE and the Node B. The UE can transmit data belonging to this process without first receiving any scheduling consent. The following QOS related information may be provided from the SRNC to the ue to initiate Qos-style E-TFC selection, logical channel multiplex transmission in MAC-e PDUs, and HARQ operation: - logical channel priority for each logical channel (eg R e 1 _ 5); - mapping between logical channels and MAC-d processes (as in Rei_5) · Allow MAC-d flow in MAC-e PDUs; - HARQ characteristics of each MAC-d process (HARQ). A HARQ profile consists of a power offset attribute and a maximum transfer quantity attribute. This power offset attribute is used in the E-TFC selection to control the bler operating point of the transmission. The maximum number of passes is used in the HARQ operation to control the maximum delay and the residual BLER of the MAC-d flow. The following 6&quot;〇s related parameters are provided by the SRNC to node b to enable scheduling and resource reservation: a power offset or E-TFC (FFS) for guaranteed bit rate (only for MAC_d with guaranteed 7L rate service) Process / Logical Channel). For scheduled transmissions, it is used to assign consent to the UES. For non-scheduled transmissions, it is used for this Node B to reserve a sufficient amount of resources. The additional mechanism requirement for optimizing the 1305469 Node B hardware is FFS (for example, the UE can inform the Node B in advance that the non-scheduled transmission is about to start); the UE considers the following principles: - The E-TFC selection is based on the Reiease 'Logical channel priority in '99, that is, the UE should maximize the transmission of high priority data; - the UE should focus on the allowed combination of the MAC-d flow in the same MAC-e PDU;

- associated with a MAC-e PDU and including MAC-d PDUs from one or several MAC-d flows, and the power offset for the E-DPDCH(s) of the DPCCH is set as follows: The UE is in the MAC-e PDU The highest priority channel in the middle selects the power offset of the HARQ profile of the MAC-d flow; considering the various problems described above with reference to Figures 1 to 4, the inventors have learned of the High Speed Upload Packet Access (HSUPA) scheme. Improvements are highly desirable. SUMMARY OF THE INVENTION One aspect of the present invention relates to the inventors' knowledge of the disadvantages of the related art. That is, in the related art, the network (ie, base station and network controller, Node B and RNC, UTRAN, etc.) is not provided with sufficient information for optimal performance, especially High Speed Upload Packet Access (HSUPA). . Based on this understanding, improvements to the HSUPA scheme have been proposed in accordance with the present invention. The present invention provides enhanced signal transmission for lower delay transmissions, and optimizing the rate request report and one of the control information MAC-e PDU formats can solve the problems of the related art. [Embodiment] The present invention has been described as being implemented in a UMTS mobile communication system. However, since the concepts and principles of the present invention can be applied to various communication schemes operating in a similar manner in accordance with common techniques, the present invention can also be applied to communication systems that operate under other communication specification types, Non-limiting exemplary embodiments of the invention are described with reference to the accompanying drawings. Improvements to the High Speed Upload Packet Access (HSUPA) scheme can be considered in the following manner: The following description of the features of the present invention will be provided with reference to the transmission of the lower delay transmissions of Figs.趁 low blanket _ late signal transmission (steps S20 ~ S50 of Figure 6)

In order to achieve maximum throughput, unnecessary delays should be minimized in the overall HSUPA (High Speed Upload Packet Access) operation. The delay item in HSUPA may consist of scheduling at the UE, HARQ retransmission, Iub interface delay, and reordering of the SRNC. The edge reordering delay will be considered later and a signalling procedure will be described to avoid unnecessary waits in the reordering queue. In the worst case, the HARQ delay can be very large. On the one hand, the uncertainty of reordering the received MAC-ePDUs should be avoided, and on the other hand all possible delays should be considered to avoid unnecessary p D U ignores. 13 1305469 However, if it is apparent that there is no need to wait for the previous p D U s ' for a particular PDU', the reordering column operation should immediately process and transmit the P D U to the higher layer. This is because unnecessary delays can ultimately cause the DPU to ignore an improper longer time in the higher layer or cause an acknowledgement (ACK or NACK) to perform AM PDUs, and thus it will affect the overall processing power. Unfortunately, because the related technology performs a small amount of signal transmission to the Cushing SRNC, the above effects caused by this delay will be unavoidable.

Figure 5 shows an example of PDU transmission delay. For the purpose of explanation, it is assumed that there are five kinds of (HARQ) processing for the UE. The actual number of such processing will depend on various conditions in the communication environment. The HARQ process from 1 to 4 starts a new transmission 〇 (transmission time interval) from 〇 to 4, respectively, and the HARQ process 5 starts a new transmission at ΤΤΙ 9. It is assumed that the MAC-e PDU 5 is correctly received at the ΤΤΙ 14 and the MAC-e PDUs from 1 to 4 reach the maximum number of retransmissions at the TTI from 20 to 23 without being successfully received by the Node B. For the sake of simplicity' further assume that MAC-ePDUs from 1 to 5 contain MAC-es PDUs from the same logical channel. Under this assumption, it is naturally assumed that all MAC-es PDUs included in the MAC-e PDUs from 1 to 4 are located before all the MAC-es PDUs included in the MAC-e PDU 5. In this example, the τ TI 2 4 smart node B implementation knows that the MAC-es PDUs in the MAC stomach e PDU 5 do not need to wait for the MAC-es PDUs in the MAC-e PDUs 1-4 (ie, the previous MAC-es PDUs). This is because all previous MAC-e PDUs transmissions failed. Even if the MAC-e PDUs 14 1305469 1-4 include MAC-es PDUs from other logical channels, it is difficult to imagine that the MAC-es PDUs before the MAC-es PDUs in the MAC-e PDU 5 will be TTI after 24 Receive, unless it is assumed that the TSN setting entity operates in reverse.

No signal is sent from Node B to the SRNC, except for the number of retransmissions of the received PDU and the initial T TI of the P D U transmission of the reordering operation. In other words, 'The Node B did not inform the SRNC of any failures in which the processing successfully decrypted the MAC-e PDU, what failed to process the maximum number of retransmissions, or failed to retransmit successfully. TTI and so on. Therefore, in the foregoing example, the MAC-es PDUs in the MAC-e PDU 5 should wait in the reordering queue of the SRNC for a longer time than actually needed, because the SRNC reordering queue does not have a previous MAC_es. Whether PDUs may be received in the future. In fact, for the SRNC, its operation is not strictly described in the current 3GPP specifications... Whether or not a timer mechanism is used, it still relies on a -window mechanism or other mechanisms. However, the U problem described here is that no information is provided to the SRNC, so that the wisdom or effective operation that minimizes delay and enhances processing power will be limited. Therefore, the inventors have understood this and have provided two possible solutions. One is to send a signal s from the UE to the SRNC, and the other is to send a signal from the Node B to the SRNC.

a) From UE to SRNC In this method, the UE will indicate 竑CDXTn

What kind of TSN 15 , 1305469 the SRNC can wait for? The above method of informing the SRNC each time the processing information can cause a large load on the Iub interface. However, it can be solved that if the node 1 checks the successfully received MAC_e PDU and uses the HARQ state, the point B can directly inform the SRNC whether it can wait or not. This is not only a simpler solution, but will also place less overhead on the Iub interface. However, one of the problems here is how to provide the e-DPCCH - reliable decoding. After successfully decoding the E_DCH payload and under the conditions listed below, the Serving Node B shall transmit a HARQ Failure Indication to the SRNC. The non-servo Node B should not transmit a HARQ failure indication. The word service node B shall transmit a HARQ failure indication to the SRNC under the following conditions: a HARQ process has not been successfully decoded and receives a new data indicator (NDI) of the same HARQ process and the number of existing HARQ retransmissions It is much higher than the lowest value of the maximum HARQ retransmission value of the MAC-d flow. A HARQ process has not been successfully decoded and the retransmission maximum of the MAC-d flow with the maximum number of HARQ retransmissions available for the ue connection already exists, or should exist to avoid the HARQ related band on the E-DPCCH (outband) Signal transmission cannot be decoded. The HARQ failure indication should be transmitted using the transport vehicle that performs the highest priority MAC-d procedure. If there is more than one highest priority MAC-d flow' then the node β should only use these MAC-d flows 17

One of the transmission vehicles of the 1305469. In order to implement the various features described above, various types and/or software components (modules) can be used in the present invention. For example, different hardware models can be used to describe the various circuits and components necessary for the steps of the method. Further, different software modules (executed by the processor and/or other hardware) may have various encodings and protocols necessary to perform the steps of the method of the present invention. In other words, the present invention provides a k-send between a base station and a network control state, which includes · detecting at least _ broadcast transmission failures based on existing broadcast retransmissions; and Provides information about the failure of the broadcast transmission of the detection to the material controller to allow for further signal processing in the future. The information provided herein may include a broadcast transmission failure indication.鸪 Detecting and providing can be performed by the base station. The base station can be a Node B. : The network controller can be a broadcast network controller. The broadcast transmission can be compared with: Automatic Repeat Request (HARQ) #Off. The detection step can further: =3. Compare the wireless transmission retransmission with a threshold. The threshold may be a maximum number of retransmissions allowed. The telling step can then be performed if the maximum number is greater than the critical value. This further signal processing reduces data transfer delays. ; ^ Provided information telling the network controller about which HARQ processing has successfully decoded _ MAC_e _, which harq processing failed on the maximum number of new transmissions I, and/or - the last unsuccessful retransmission already exists Transmission time interval. The step of providing information may further include: transmitting in the case of one of the two - a HARQ failure indication to the network = 18 1305469: receiving a new data for the same harq processing if a HARQ process has not been successfully decoded The indicator and the number of existing harq retransmissions is much larger than the lowest value of the maximum HARQ retransmission value of the MAC-d flow, or if a HARQ process has not been successfully decoded and has the highest maximum HARQ retransmission valid for the ue connection The MAC-d flow maximum retransmission already exists or should already exist to prevent the HARQ related out-of-band signal transmission on the E-DPCCH from being decoded. Φ The HARQ failure can only be transmitted by using a transport vehicle that performs a highest priority mac-d flow. If there is more than one MAC-d process with the highest priority, only the transport vehicles associated with these MAc_d processes are selected and used. Furthermore, the present invention provides a method for transmitting a signal between a base station and a network controller, which includes receiving one according to at least one broadcast transmission failure detected based on re-transmission of several existing broadcast transmissions. The broadcast transmission failure indication; and performing the forward signal processing according to the received broadcast transmission failure indication. Furthermore, the present invention provides a method for improving high speed upload packet access signal transmission by using a user equipment and a network controller in a communication system, the method comprising: detecting a plurality of existing broadcast transmissions according to the detection Round retransmission to provide information about the failure of the broadcast transmission to the network controller; and avoiding unnecessary agreement data unit ignoring based on the information provided thereby minimizing scheduling on the user equipment and on the network The controller performs harq retransmission, performs Iub interface signaling, and/or performs reordering delays to increase data processing capabilities.

19

Claims (1)

1305469

month

Picking up, applying for a patent range: 1. A method for transmitting a signal between a base station and a network controller, comprising at least: a detecting step of detecting at least one broadcast according to a plurality of existing broadcast transmission retransmissions The transmission fails; and a step of providing information about the detected broadcast transmission failure to the network controller to allow for further signal processing thereafter.

2. The method of claim 1, wherein the information provided includes a broadcast transmission failure indication. 3. The method of claim 1, wherein the detecting and providing step is performed by the base station.

4. The method of claim 3, wherein the base station is a Node B. 5. The method of claim 1, wherein the network controller is a broadcast network controller. 6. The method of claim 1, wherein the broadcast transmission is related to a hybrid automatic repeat request. 22 1305469

7. The method of claim 1, wherein the detecting step further comprises: a comparing step of comparing the number of broadcast transmission retransmissions with a threshold value. 8. The method of claim 7, wherein the threshold is one of a maximum number of retransmissions allowed.

9. The method of claim 8, wherein if the maximum number is greater than the threshold, then a step of informing is performed. 10. The method of claim 9, wherein the further signal processing reduces data transmission delay. 1 1. The method of claim 6, wherein the information provided informs the network controller as to which HARQ process has been successfully solved.

The secret one MAC-e PDU, which HARQ process fails in the case of the maximum number of retransmissions, and/or which transmission time interval has existed in the last unsuccessful retransmission. 12. The method of claim 6, wherein the providing the information step further comprises: informing a step of transmitting a HARQ failure in any of the following conditions 23 1305469

Indicating to the network controller: A HARQ process has not been successfully decoded to receive a new profile indicator for the same HARQ process and the number of existing HARQ retransmissions is much greater than the minimum value of the maximum HARQ retransmission value of a MAC-d process ;or

A maximum retransmission of a MAC-d procedure that has not been successfully decoded and has the highest maximum HARQ retransmission valid for a UE connection already exists or should have existed to avoid HARQ related out-of-band signaling on an E-DPCCH. Is decoded. The method of claim 12, wherein the HARQ failure indication is transmitted by using a carrier vehicle that executes one of the highest priority MAC-d flows. 1 4. The method of claim 13, wherein if there is more than one MAC-d process with the highest priority, only select and use

A transport vehicle associated with these MAC-d processes. The method of claim 1, wherein the detecting and providing step is performed by a mobile station connected to the base station. 1 6. The method of claim 15 of the patent application, further comprising: 24 1305469 month-day repair (3⁄4 positive replacement page 97 8. 2 1 - 2_ reporting step, which takes the action The buffer status of the station reports the base station and/or the network controller; by notifying the available power information and the amount of data buffer in the mobile station that does not receive the schedule permission; or by when the report is When a mobile station that receives a scheduled license is generated, it informs the amount of buffering between the times.

1 7. The method of claim 15, wherein the detecting step further comprises: a transmitting step, when there is no permission rate of the mobile station or when there is some permission rate of the mobile station, A mobile station transmits control information to the base station and/or the network controller. 1 8 · The method of claim 15, wherein the method further comprises:

A decision step of deciding to use the same or different MAC-e PDU format for transmission by confirming whether to allow control information and multiplex processing of MAC-e PDUs; and forming a M A C - e control message based on the decision. 1 9. A method for transmitting a signal between a base station and a network controller, comprising: a receiving step of receiving a broadcast transmission failure indication based on re-transmitting 25.1305469 transmission failures based on an existing number of broadcast transmissions And executing a step of performing further signal processing in accordance with the received broadcast transmission failure indication. A method for utilizing a user equipment and a network controller to facilitate high speed upload packet access signal transmission in a communication system, the method comprising at least: a φ providing step based on an existing number of broadcasts Transmitting retransmission to provide information about the failure of the broadcast transmission to the network controller; and avoiding steps, based on the provided information, by performing scheduling on the user equipment, executing on the network controller side The delay caused by HARQ retransmission, Iub interface signaling, and/or reordering is minimized, avoiding unnecessary protocol data unit ignoring and improving data processing throughput. 1305469 First position. "Yi Hao Wei Kou Lunian" monthly revision year and month repair (i) is replacing I (four) poor... ' lQ7 R 21__ 柒, designated representative map: (1), the designated representative figure of this case is: Figure 6. (2) The representative symbol of this representative diagram is a simple description: 120 Broadcast Network Controller (RNC) 100 Mobile Station (UE) 11 0 Base Station (Node B) 捌 If there is a chemical formula in this case, please reveal the best indication of the characteristics of the invention. Chemical formula: ❿ 4

Method and apparatus for delivery of data-based/voice services over piconets and wireless lans (wlans) coupled to 3gpp devices including protocol architecture and information elements relating to short message service (sms) over wlans

Automatic repeat request (ARQ) protocol employing first information indicating whether to perform retransmission of an uplink data packet and second information indicating a transport format for the retransmission